/* simtrace2-sniff - main program for the host PC to communicate with the * SIMtrace 2 firmware in sniffer mode * * (C) 2016 by Harald Welte * (C) 2018 by sysmocom -s.f.m.c. GmbH, Author: Kevin Redon * * This program is free software; you can redistribute it and/or * modify it under the terms of the GNU General Public License * as published by the Free Software Foundation; either version 2 * of the License, or (at your option) any later version. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the * GNU General Public License for more details. * * You should have received a copy of the GNU General Public License * along with this program; if not, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. */ #include #include #include #include #include #include #include #include #define _GNU_SOURCE #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include #include /* transport to a SIMtrace device */ struct st_transport { /* USB */ struct libusb_device_handle *usb_devh; struct { uint8_t in; uint8_t out; uint8_t irq_in; } usb_ep; }; const struct value_string change_flags[] = { { SNIFF_CHANGE_FLAG_CARD_INSERT, "card inserted" }, { SNIFF_CHANGE_FLAG_CARD_EJECT, "card ejected" }, { SNIFF_CHANGE_FLAG_RESET_ASSERT, "reset asserted" }, { SNIFF_CHANGE_FLAG_RESET_DEASSERT, "reset de-asserted" }, { SNIFF_CHANGE_FLAG_TIMEOUT_WT, "data transfer timeout" }, { 0, NULL } }; const struct value_string data_flags[] = { { SNIFF_DATA_FLAG_ERROR_INCOMPLETE, "incomplete" }, { SNIFF_DATA_FLAG_ERROR_MALFORMED, "malformed" }, { SNIFF_DATA_FLAG_ERROR_CHECKSUM, "checksum error" }, { 0, NULL } }; static void print_flags(const struct value_string* flag_meanings, uint32_t nb_flags, uint32_t flags) { uint32_t i; for (i = 0; i < nb_flags; i++) { if (flags & flag_meanings[i].value) { printf("%s", flag_meanings[i].str); flags &= ~flag_meanings[i].value; if (flags) { printf(", "); } } } } static int process_change(const uint8_t *buf, int len) { /* check if there is enough data for the structure */ if (len < sizeof(struct sniff_change)) { return -1; } struct sniff_change *change = (struct sniff_change *)buf; printf("Card state change: "); if (change->flags) { print_flags(change_flags, ARRAY_SIZE(change_flags), change->flags); printf("\n"); } else { printf("no changes\n"); } return 0; } /* Table 7 of ISO 7816-3:2006 */ static const uint16_t fi_table[] = { 372, 372, 558, 744, 1116, 1488, 1860, 0, 0, 512, 768, 1024, 1536, 2048, 0, 0, }; /* Table 8 from ISO 7816-3:2006 */ static const uint8_t di_table[] = { 0, 1, 2, 4, 8, 16, 32, 64, 12, 20, 2, 4, 8, 16, 32, 64, }; static int process_fidi(const uint8_t *buf, int len) { /* check if there is enough data for the structure */ if (lenfidi>>4], di_table[fidi->fidi&0x0f]); return 0; } static int process_data(enum simtrace_msg_type_sniff type, const uint8_t *buf, int len) { /* check if there is enough data for the structure */ if (len < sizeof(struct sniff_data)) { return -1; } struct sniff_data *data = (struct sniff_data *)buf; /* check if the data is available */ if (len < sizeof(struct sniff_data) + data->length) { return -2; } /* check type */ if (type != SIMTRACE_MSGT_SNIFF_ATR && type != SIMTRACE_MSGT_SNIFF_PPS && type != SIMTRACE_MSGT_SNIFF_TPDU) { return -3; } /* Print message */ switch (type) { case SIMTRACE_MSGT_SNIFF_ATR: printf("ATR"); break; case SIMTRACE_MSGT_SNIFF_PPS: printf("PPS"); break; case SIMTRACE_MSGT_SNIFF_TPDU: printf("TPDU"); break; default: printf("???"); break; } if (data->flags) { printf(" ("); print_flags(data_flags, ARRAY_SIZE(data_flags), data->flags); printf(")"); } printf(": "); uint16_t i; for (i = 0; i < data->length; i++) { printf("%02x ", data->data[i]); } printf("\n"); /* Send message as GSNTAP */ switch (type) { case SIMTRACE_MSGT_SNIFF_ATR: osmo_st2_gsmtap_send_apdu(GSMTAP_SIM_ATR, data->data, data->length); break; case SIMTRACE_MSGT_SNIFF_TPDU: /* TPDU is now considered as APDU since SIMtrace sends complete TPDU */ osmo_st2_gsmtap_send_apdu(GSMTAP_SIM_APDU, data->data, data->length); break; default: break; } return 0; } /*! \brief Process an incoming message from the SIMtrace2 */ static int process_usb_msg(const uint8_t *buf, int len) { /* check if enough data for the header is present */ if (len < sizeof(struct simtrace_msg_hdr)) { return 0; } /* check if message is complete */ struct simtrace_msg_hdr *msg_hdr = (struct simtrace_msg_hdr *)buf; if (len < msg_hdr->msg_len) { return 0; } //printf("msg: %s\n", osmo_hexdump(buf, msg_hdr->msg_len)); /* check for message class */ if (SIMTRACE_MSGC_SNIFF != msg_hdr->msg_class) { /* we only care about sniffing messages */ return msg_hdr->msg_len; /* discard non-sniffing messaged */ } /* process sniff message payload */ buf += sizeof(struct simtrace_msg_hdr); len -= sizeof(struct simtrace_msg_hdr); switch (msg_hdr->msg_type) { case SIMTRACE_MSGT_SNIFF_CHANGE: process_change(buf, len); break; case SIMTRACE_MSGT_SNIFF_FIDI: process_fidi(buf, len); break; case SIMTRACE_MSGT_SNIFF_ATR: case SIMTRACE_MSGT_SNIFF_PPS: case SIMTRACE_MSGT_SNIFF_TPDU: process_data(msg_hdr->msg_type, buf, len); break; default: printf("unknown SIMtrace msg type 0x%02x\n", msg_hdr->msg_type); break; } return msg_hdr->msg_len; } /*! Transport to SIMtrace device (e.g. USB handle) */ static struct st_transport _transp; static void run_mainloop() { int rc; uint8_t buf[16*256]; unsigned int i, buf_i = 0; int xfer_len; printf("Entering main loop\n"); while (true) { /* read data from SIMtrace2 device (via USB) */ rc = libusb_bulk_transfer(_transp.usb_devh, _transp.usb_ep.in, &buf[buf_i], sizeof(buf)-buf_i, &xfer_len, 100000); if (rc < 0 && rc != LIBUSB_ERROR_TIMEOUT && rc != LIBUSB_ERROR_INTERRUPTED && rc != LIBUSB_ERROR_IO) { fprintf(stderr, "BULK IN transfer error; rc=%d\n", rc); return; } /* dispatch any incoming data */ if (xfer_len > 0) { //printf("URB: %s\n", osmo_hexdump(&buf[buf_i], xfer_len)); buf_i += xfer_len; if (buf_i >= sizeof(buf)) { perror("preventing USB buffer overflow"); return; } int processed; while ((processed = process_usb_msg(buf, buf_i)) > 0) { if (processed > buf_i) { break; } for (i = processed; i < buf_i; i++) { buf[i-processed] = buf[i]; } buf_i -= processed; } } } } static void print_welcome(void) { printf("simtrace2-sniff - Phone-SIM card communication sniffer \n" "(C) 2010-2017 by Harald Welte \n" "(C) 2018 by Kevin Redon \n" "\n" ); } static void print_help(void) { printf( "\t-h\t--help\n" "\t-i\t--gsmtap-ip\tA.B.C.D\n" "\t-k\t--keep-running\n" "\t-V\t--usb-vendor\tVENDOR_ID\n" "\t-P\t--usb-product\tPRODUCT_ID\n" "\t-C\t--usb-config\tCONFIG_ID\n" "\t-I\t--usb-interface\tINTERFACE_ID\n" "\t-S\t--usb-altsetting ALTSETTING_ID\n" "\t-A\t--usb-address\tADDRESS\n" "\n" ); } static const struct option opts[] = { { "help", 0, 0, 'h' }, { "gsmtap-ip", 1, 0, 'i' }, { "keep-running", 0, 0, 'k' }, { "usb-vendor", 1, 0, 'V' }, { "usb-product", 1, 0, 'P' }, { "usb-config", 1, 0, 'C' }, { "usb-interface", 1, 0, 'I' }, { "usb-altsetting", 1, 0, 'S' }, { "usb-address", 1, 0, 'A' }, { NULL, 0, 0, 0 } }; /* Known USB device with SIMtrace firmware supporting sniffer */ static const struct dev_id compatible_dev_ids[] = { { USB_VENDOR_OPENMOKO, USB_PRODUCT_SIMTRACE2 }, { USB_VENDOR_OPENMOKO, USB_PRODUCT_NGFF_CARDEM }, { 0, 0 } }; static void signal_handler(int signal) { switch (signal) { case SIGINT: exit(0); break; default: break; } } int main(int argc, char **argv) { int i, rc, ret; print_welcome(); /* Parse arguments */ char *gsmtap_host = "127.0.0.1"; int keep_running = 0; int vendor_id = -1, product_id = -1, addr = -1, config_id = -1, if_num = -1, altsetting = -1; while (1) { int option_index = 0; int c = getopt_long(argc, argv, "hi:kV:P:C:I:S:A:", opts, &option_index); if (c == -1) break; switch (c) { case 'h': print_help(); exit(0); break; case 'i': gsmtap_host = optarg; break; case 'k': keep_running = 1; break; case 'V': vendor_id = strtol(optarg, NULL, 16); break; case 'P': product_id = strtol(optarg, NULL, 16); break; case 'C': config_id = atoi(optarg); break; case 'I': if_num = atoi(optarg); break; case 'S': altsetting = atoi(optarg); break; case 'A': addr = atoi(optarg); break; } } /* Scan for available SIMtrace USB devices supporting sniffing */ rc = libusb_init(NULL); if (rc < 0) { fprintf(stderr, "libusb initialization failed\n"); goto do_exit; } struct usb_interface_match ifm_scan[16]; int num_interfaces = osmo_libusb_find_matching_interfaces(NULL, compatible_dev_ids, USB_CLASS_PROPRIETARY, SIMTRACE_SNIFFER_USB_SUBCLASS, -1, ifm_scan, ARRAY_SIZE(ifm_scan)); if (num_interfaces <= 0) { perror("No compatible USB devices found"); goto do_exit; } /* Only keep USB matching arguments */ struct usb_interface_match ifm_filtered[ARRAY_SIZE(ifm_scan)]; int num_filtered = 0; for (i = 0; i < num_interfaces; i++) { if (vendor_id>=0 && vendor_id!=ifm_scan[i].vendor) { continue; } if (product_id>=0 && product_id!=ifm_scan[i].product) { continue; } if (config_id>=0 && config_id!=ifm_scan[i].configuration) { continue; } if (if_num>=0 && if_num!=ifm_scan[i].interface) { continue; } if (altsetting>=0 && altsetting!=ifm_scan[i].altsetting) { continue; } if (addr>=0 && addr!=ifm_scan[i].addr) { continue; } ifm_filtered[num_filtered++] = ifm_scan[i]; } if (1!=num_filtered) { perror("No individual matching USB devices found"); printf("Available USB devices:\n"); for (i = 0; i < num_interfaces; i++) { printf("\t%04x:%04x Addr=%u, Path=%s, Cfg=%u, Intf=%u, Alt=%u: %d/%d/%d ", ifm_scan[i].vendor, ifm_scan[i].product, ifm_scan[i].addr, ifm_scan[i].path, ifm_scan[i].configuration, ifm_scan[i].interface, ifm_scan[i].altsetting, ifm_scan[i].class, ifm_scan[i].sub_class, ifm_scan[i].protocol); libusb_device_handle *dev_handle; rc = libusb_open(ifm_scan[i].usb_dev, &dev_handle); if (rc < 0) { printf("\n"); perror("Cannot open device"); continue; } char strbuf[256]; rc = libusb_get_string_descriptor_ascii(dev_handle, ifm_scan[i].string_idx, (unsigned char *)strbuf, sizeof(strbuf)); libusb_close(dev_handle); if (rc < 0) { printf("\n"); perror("Cannot read string"); continue; } printf("(%s)\n", strbuf); } goto do_exit; } struct usb_interface_match ifm_selected = ifm_filtered[0]; printf("Using USB device %04x:%04x Addr=%u, Path=%s, Cfg=%u, Intf=%u, Alt=%u: %d/%d/%d ", ifm_selected.vendor, ifm_selected.product, ifm_selected.addr, ifm_selected.path, ifm_selected.configuration, ifm_selected.interface, ifm_selected.altsetting, ifm_selected.class, ifm_selected.sub_class, ifm_selected.protocol); libusb_device_handle *dev_handle; rc = libusb_open(ifm_selected.usb_dev, &dev_handle); if (rc < 0) { printf("\n"); perror("Cannot open device"); } char strbuf[256]; rc = libusb_get_string_descriptor_ascii(dev_handle, ifm_selected.string_idx, (unsigned char *)strbuf, sizeof(strbuf)); libusb_close(dev_handle); if (rc < 0) { printf("\n"); perror("Cannot read string"); } printf("(%s)\n", strbuf); rc = osmo_st2_gsmtap_init(gsmtap_host); if (rc < 0) { perror("unable to open GSMTAP"); goto close_exit; } signal(SIGINT, &signal_handler); do { _transp.usb_devh = osmo_libusb_open_claim_interface(NULL, NULL, &ifm_selected); if (!_transp.usb_devh) { fprintf(stderr, "can't open USB device\n"); goto close_exit; } rc = libusb_claim_interface(_transp.usb_devh, ifm_selected.interface); if (rc < 0) { fprintf(stderr, "can't claim interface %d; rc=%d\n", ifm_selected.interface, rc); goto close_exit; } rc = osmo_libusb_get_ep_addrs(_transp.usb_devh, ifm_selected.interface, &_transp.usb_ep.out, &_transp.usb_ep.in, &_transp.usb_ep.irq_in); if (rc < 0) { fprintf(stderr, "can't obtain EP addrs; rc=%d\n", rc); goto close_exit; } run_mainloop(); ret = 0; if (_transp.usb_devh) libusb_release_interface(_transp.usb_devh, 0); close_exit: if (_transp.usb_devh) libusb_close(_transp.usb_devh); if (keep_running) sleep(1); } while (keep_running); libusb_exit(NULL); do_exit: return ret; }